Image sensor with time overlapping image output

ABSTRACT

An image sensor system with an image sensor that generates a first image and a second image. The first and second images are transmitted to a processor in a time overlapping manner. By way of example, the images may be transferred to the processor in an interleaving manner or provided on separate dedicated busses.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 10/445,256 filed on May 23, 2003, which is a continuation-in-part of application Ser. No. 10/236,515 filed on Sep. 6, 2002, claiming priority to provisional application No. 60/345,672 filed on Jan. 5, 2002, and to provisional application No. 60/358,611 filed on Feb. 21, 2002, and which claims priority under 35 U.S.C. §119(e) to provisional application No. 60/455,436 filed on Mar. 15, 2003. This application is also a continuation-in-part of U.S. patent application Ser. No. 12/534,874 filed on Aug. 4, 2009, which is a continuation of U.S. patent application Ser. No. 10/868,407 filed on Jun. 14, 2004, now U.S. Pat. No. 7,612,817, which is a continuation of U.S. patent application Ser. No. 10/183,218 filed on Jun. 26, 2002, now U.S. Pat. No. 6,795,117, which claims priority under 35 U.S.C §119(e) to provisional application No. 60/333,216 filed on Nov. 6, 2001, to provisional application No. 60/338,465 filed on Dec. 3, 2001 and to provisional application No. 60/345,672 filed on Jan. 5, 2002.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The subject matter disclosed generally relates to the field of semiconductor image sensors.

2. Background Information

Photographic equipment such as digital cameras and digital camcorders contain electronic image sensors that capture light for processing into a still or video image, respectively. There are two primary types of electronic image sensors, charge coupled devices (CCDs) and complimentary metal oxide semiconductor (CMOS) sensors. CCD image sensors have relatively high signal to noise ratios (SNR) that provide quality images. Additionally, CCDs can be fabricated to have pixel arrays that are relatively small while conforming with most camera and video resolution requirements. A pixel is the smallest discrete element of an image. For these reasons, CCDs are used in most commercially available cameras and camcorders.

CMOS sensors are faster and consume less power than CCD devices. Additionally, CMOS fabrication processes are used to make many types of integrated circuits. Consequently, there is a greater abundance of manufacturing capacity for CMOS sensors than CCD sensors.

To date there has not been developed a CMOS sensor that has the same SNR and pixel pitch requirements as commercially available CCD sensors. Pixel pitch is the space between the centers of adjacent pixels. It would be desirable to provide a CMOS sensor that has relatively high SNR while providing a commercially acceptable pixel pitch.

The image sensor is typically connected to an external processor and external memory. The external memory stores data from the image sensor. The processor processes the stored data. To improve picture quality it is sometimes desirable to capture two different images of the same picture. With CCD sensors there is an inherent delay between capturing the first image and capturing the second image. The image may move during this delay. This image movement may degrade the quality of the resultant picture. It would be desirable to decrease the time required to capture and transmit images from the pixel array. It would also be desirable to provide a low noise, high speed, high resolution image sensor that can utilize external memory.

BRIEF SUMMARY OF THE INVENTION

An image sensor system that includes an image sensor that transmits a first image and a second image to a processor in a time overlapping manner.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic of an embodiment of an image sensor;

FIG. 2 is an illustration of a method for storing pixel data in an external memory for a still image;

FIG. 3 is an illustration of a method for retrieving and combining pixel data for a still image;

FIG. 4 is an illustration of an alternate method for retrieving and combining pixel data;

FIG. 5 is an illustration of alternate method for retrieving and combining pixel data;

FIG. 6 is an illustration of alternate method for retrieving and combining pixel data;

FIG. 7 is an illustration of alternate method for retrieving and combining pixel data;

FIG. 8 is an illustration showing a method for storing and combining pixel data for a video image;

FIG. 9 is another illustration showing the method for storing and combining pixel data for a video image;

FIG. 10 is an illustration showing a method for converting the resolution of pixel data;

FIG. 11 is an illustration showing an alternate method for converting the resolution of the pixel data;

FIG. 12 is an illustration showing an alternate method for converting the resolution of the pixel data;

FIG. 13 is a schematic of an embodiment of a pixel of the image sensor;

FIG. 14 is a schematic of an embodiment of a light reader circuit of the image sensor;

FIG. 15 is a flowchart for a first mode of operation of the image sensor;

FIG. 16 is a timing diagram for the first mode of operation of the image sensor;

FIG. 17 is a diagram showing the levels of a signal across a photodiode of a pixel;

FIG. 18 is a schematic for a logic circuit for generating the timing diagrams of FIG. 16;

FIG. 19 is a schematic of a logic circuit for generating a RST signal for a row of pixels;

FIG. 20 is a timing diagram for the logic circuit shown in FIG. 19;

FIG. 21 is a flowchart showing a second mode of operation of the image sensor;

FIG. 22 is a timing diagram for the second mode of operation of the image sensor;

FIG. 23a is a schematic of an alternate embodiment of an image sensor system;

FIG. 23b is a schematic of an alternate embodiment of an image sensor system;

FIG. 24 is a schematic of an alternate embodiment of an image sensor system;

FIG. 25 is a schematic of an alternate embodiment of an image sensor system;

FIG. 26 is a schematic of an alternate embodiment of an external processor;

FIG. 27 is a schematic of an alternate embodiment of an image sensor system;

FIG. 28 is a schematic of an embodiment of a processor for the processor shown in FIG. 27;

FIG. 29 is a schematic of an embodiment of a DMA controller for the processor shown in FIG. 28.

DETAILED DESCRIPTION

Disclosed is an image sensor system with an image sensor that generates a first image and a second image. The first and second images are transmitted to a processor in a time overlapping manner. By way of example, the images may be transferred to the processor in an interleaving manner or provided on separate dedicated busses.

The entire image sensor is preferably constructed with CMOS fabrication processes and circuits. The CMOS image sensor has the characteristics of being high speed, low power consumption, small pixel pitch and a high SNR.

Referring to the drawings more particularly by reference numbers, FIG. 1 shows an image sensor 10. The image sensor 10 includes a pixel array 12 that contains a plurality of individual photodetecting pixels 14. The pixels 14 are arranged in a two-dimensional array of rows and columns.

The pixel array 12 is coupled to a light reader circuit 16 by a bus 18 and to a row decoder 20 by control lines 22. The row decoder 20 can select an individual row of the pixel array 12. The light reader 16 can then read specific discrete columns within the selected row. Together, the row decoder 20 and light reader 16 allow for the reading of an individual pixel 14 in the array 12.

The light reader 16 may be coupled to an analog to digital converter 24 (ADC) by output line(s) 26. The ADC 24 generates a digital bit string that corresponds to the amplitude of the signal provided by the light reader 16 and the selected pixels 14.

The ADC 24 is coupled to a pair of first image buffers 28 and 30, and a pair of second image buffers 32 and 34 by lines 36 and switches 38, 40 and 42. The first image buffers 28 and 30 are coupled to a memory controller 44 by lines 46 and a switch 48. The memory controller 44 can more generally be referred to as a data interface. The second image buffers 32 and 34 are coupled to a data combiner 50 by lines 52 and a switch 54. The memory controller 44 and data combiner 50 are connected to a read back buffer 56 by lines 58 and 60, respectively. The output of the read back buffer 56 is connected to the controller 44 by line 62. The data combiner 50 is connected to the memory controller 44 by line 64. Additionally, the controller 44 is connected to the ADC 24 by line 66.

The memory controller 44 is coupled to an external bus 68 by a controller bus 70. The external bus 68 is coupled to an external processor 72 and external memory 74. The bus 70, processor 72 and memory 74 are typically found in existing digital cameras, cameras and cell phones.

To capture a still picture image, the light reader 16 retrieves a first image of the picture from the pixel array 12 line by line. The switch 38 is in a state that connects the ADC 24 to the first image buffers 28 and 30. Switches 40 and 48 are set so that data is entering one buffer 28 or 30 and being retrieved from the other buffer 30 or 28 by the memory controller 44. For example, the second line of the pixel may be stored in buffer 30 while the first line of pixel data is being retrieved from buffer 28 by the memory controller 44 and stored in the external memory 74.

When the first line of the second image of the picture is available the switch 38 is selected to alternately store first image data and second image data in the first 28 and 30, and second 32 and 34 image buffers, respectively. Switches 48 and 54 may be selected to alternatively store first and second image data into the external memory 74 in an interleaving manner. This process is depicted in FIG. 2.

There are multiple methods for retrieving and combining the first and second image data. As shown in FIG. 3, in one method each line of the first and second images are retrieved from the external memory 74 at the memory data rate, stored in the read back buffer 56, combined in the data combiner 50 and transmitted to the processor 72 at the processor data rate. Alternatively, the first and second images may be stored in the read back buffer 56 and then provided to the processor 72 in an interleaving or concatenating manner without combining the images in the combiner 50. This technique allows the processor 72 to process the data manner in different ways.

FIG. 4 shows an alternative method wherein the external processor 72 combines the pixel data. A line of the first image is retrieved from the external memory 74 and stored in the read back buffer 56 at the memory data rate and then transferred to the external processor 72 at the processor data rate. A line of the second image is then retrieved from the external memory 74, stored in the read back buffer 56, and transferred to the external processor 72. This sequence continues for each line of the first and second images. Alternatively, the entire first image may be retrieved from the external memory 74, stored in the read back buffer 56 and transferred to the external processor 72, one line at a time, as shown in FIG. 5. Each line of the second image is then retrieved from the external memory 74, stored in the read back buffer 56 and transferred to the external processor 72.

In the event the processor data rate is the same as the memory data rate the processor 72 may directly retrieve the pixel data rate from the external memory 74 in either an interleaving or concatenating manner as shown in FIGS. 6 and 7, respectively. For all of the techniques described, the memory controller 44 provides arbitration for data transfer between the image sensor 10, the processor 72 and memory 74. To reduce noise in the image sensor 10, the controller 44 preferably transfers data when the light reader 16 is not retrieving output signals.

To capture a video picture, the lines of pixel data of the first image of the picture may be stored in the external memory 74. When the first line of the second image of the picture is available, the first line of the first image is retrieved from memory 74 at the memory data rate and combined in the data combiner 50 as shown in FIGS. 8 and 9. The combined data is transferred to the external processor 72 at the processor data rate. As shown in FIG. 9, the external memory is both outputting and inputting lines of pixel data from the first image at the memory data rate.

For video capture the buffers 28, 30, 32 and 34 may perform a resolution conversion of the incoming pixel data. There are two common video standards NTSC and PAL. NTSC requires 480 horizontal lines. PAL requires 590 horizontal lines. To provide high still image resolution the pixel array 12 may contain up to 1500 horizontal lines. The image sensor converts the output data into a standard format. Converting on board the image sensor reduces the overhead on the processor 72.

FIG. 10 shows a technique for converting the resolution and reducing the amount of data. Reducing data lowers the noise and power consumption of the image sensor. Additionally, lower data reduces the memory requirements of the external memory. The first method reduces 4 contiguous columns and four contiguous rows of pixels to 2 columns and 2 rows of pixels. The pixel array 12 includes a 4 by 4 pixel group containing red (R), green (G) and blue (B) pixels arranged in a Bayer pattern. The 4 by 4 array is reduced to a 2 by 2 array in accordance with the following equations: R=¼*(R ₁ +R ₂ +R ₃ +R ₄)  (1) B=¼*(B ₁ +B ₂ +B ₃ +B ₄)  (2) G _(B)=½*(G ₁ +G ₂)  (3) G _(R)=½*(G ₃ +G ₄)  (4) The net effect is a 75% reduction in the data rate, arranged in a Bayer pattern.

FIG. 11 shows an alternative method for resolution conversion. The second technique provides a 4:2:0 encoding that is compatible with MPEG-2. The conversion is performed using the following equations: R=¼*(R ₁ +R ₂ +R ₃ +R ₄)  (5) B=¼*(B ₁ +B ₂ +B ₃ +B ₄)  (6) G _(B)=½*(G ₁ +G ₂)  (7) G _(R)=½*(G ₃ +G ₄)  (8) G _(BB)=½*(G ₅ +G ₆)  (9) G _(RR)=½*(G ₇ +G ₈)  (10) The net effect is a 62.5% reduction in the data rate.

FIG. 12 shows yet another alternative resolution conversion method. The third method provides a 4:2:2 encoding technique using the following equations: G ₁₂=½*(G ₁ +G ₂)  (11) G ₃₄=½*(G ₃ +G ₄)  (12) G ₅₆=½*(G ₅ +G ₆)  (13) G ₇₈=½*(G ₇ +G ₈)  (14) R ₁₂=½*(R ₁ +R ₂)  (15) R ₃₄=½*(R ₃ +R ₄)  (16) B ₁₂=½*(B ₁ +B ₂)  (17) B ₃₄=½*(B ₃ +B ₄)  (18) The net effect is a 50% reduction in the data rate.

To conserve energy the memory controller 44 may power down the external memory 74 when memory is not receiving or transmitting data. To achieve this function the controller 44 may have a power control pin 76 connected to the CKE pin of a SDRAM (see FIG. 1).

FIG. 13 shows an embodiment of a cell structure for a pixel 14 of the pixel array 12. The pixel 14 may contain a photodetector 100. By way of example, the photodetector 100 may be a photodiode. The photodetector 100 may be connected to a reset transistor 112. The photodetector 100 may also be coupled to a select transistor 114 through a level shifting transistor 116. The transistors 112, 114 and 116 may be field effect transistors (FETs).

The gate of reset transistor 112 may be connected to a RST line 118. The drain node of the transistor 112 may be connected to IN line 120. The gate of select transistor 114 may be connected to a SEL line 122. The source node of transistor 114 may be connected to an OUT line 124. The RST 118 and SEL lines 122 may be common for an entire row of pixels in the pixel array 12. Likewise, the IN 120 and OUT 124 lines may be common for an entire column of pixels in the pixel array 12. The RST line 118 and SEL line 122 are connected to the row decoder 20 and are part of the control lines 22.

FIG. 14 shows an embodiment of a light reader circuit 16. The light reader 16 may include a plurality of double sampling capacitor circuits 150 each connected to an OUT line 124 of the pixel array 12. Each double sampling circuit 150 may include a first capacitor 152 and a second capacitor 154. The first capacitor 152 is coupled to the OUT line 124 and ground GND1 156 by switches 158 and 160, respectively. The second capacitor 154 is coupled to the OUT line 124 and ground GND1 by switches 162 and 164, respectively. Switches 158 and 160 are controlled by a control line SAM1 166. Switches 162 and 164 are controlled by a control line SAM2 168. The capacitors 152 and 154 can be connected together to perform a voltage subtraction by closing switch 170. The switch 170 is controlled by a control line SUB 172.

The double sampling circuits 150 are connected to an operational amplifier 180 by a plurality of first switches 182 and a plurality of second switches 184. The amplifier 180 has a negative terminal − coupled to the first capacitors 152 by the first switches 182 and a positive terminal + coupled to the second capacitors 154 by the second switches 184. The operational amplifier 180 has a positive output + connected to an output line OP 188 and a negative output − connected to an output line OM 186. The output lines 186 and 188 are connected to the ADC 24 (see FIG. 1).

The operational amplifier 180 provides an amplified signal that is the difference between the voltage stored in the first capacitor 152 and the voltage stored in the second capacitor 154 of a sampling circuit 150 connected to the amplifier 180. The gain of the amplifier 180 can be varied by adjusting the variable capacitors 190. The variable capacitors 190 may be discharged by closing a pair of switches 192. The switches 192 may be connected to a corresponding control line (not shown). Although a single amplifier is shown and described, it is to be understood that more than one amplifier can be used in the light reader circuit 16.

FIGS. 15 and 16 show an operation of the image sensor 10 in a first mode also referred to as a low noise mode. In process block 300 a reference signal is written into each pixel 14 of the pixel array and then a first reference output signal is stored in the light reader 16. Referring to FIGS. 13 and 16, this can be accomplished by switching the RST 118 and IN 120 lines from a low voltage to a high voltage to turn on transistor 112. The RST line 118 is driven high for an entire row. IN line 120 is driven high for an entire column. In the preferred embodiment, RST line 118 is first driven high while the IN line 120 is initially low.

The RST line 118 may be connected to a tri-state buffer (not shown) that is switched to a tri-state when the IN line 120 is switched to a high state. This allows the gate voltage to float to a value that is higher than the voltage on the IN line 120. This causes the transistor 112 to enter the triode region. In the triode region the voltage across the photodiode 100 is approximately the same as the voltage on the IN line 120. Generating a higher gate voltage allows the photodetector to be reset at a level close to Vdd. CMOS sensors of the prior art reset the photodetector to a level of Vdd-Vgs, where Vgs can be up to 1 V.

The SEL line 122 is also switched to a high voltage level which turns on transistor 114. The voltage of the photodiode 100 is provided to the OUT line 124 through level shifter transistor 116 and select transistor 114. The SAM1 control line 166 of the light reader 16 (see FIG. 14) is selected so that the voltage on the OUT line 124 is stored in the first capacitor 152.

Referring to FIG. 15, in process block 302 the pixels of the pixel array are then reset and reset output signals are then stored in the light reader 16. Referring to FIGS. 13 and 16 this can be accomplished by driving the RST line 118 low to turn off the transistor 112 and reset the pixel 14. Turning off the transistor 112 will create reset noise, charge injection and clock feedthrough voltage that resides across the photodiode 100. As shown in FIG. 17 the noise reduces the voltage at the photodetector 100 when the transistor 112 is reset.

The SAM2 line 168 is driven high, the SEL line 122 is driven low and then high again, so that a level shifted voltage of the photodiode 100 is stored as a reset output signal in the second capacitor 154 of the light reader circuit 16. Process blocks 300 and 302 are repeated for each pixel 14 in the array 12.

Referring to FIG. 15, in process block 304 the reset output signals are then subtracted from the first reference output signals to create noise output signals that are then converted to digital bit strings by ADC 24. The digital output data is stored within the external memory 74 in accordance with one of the techniques described in FIG. 2, 3, 8 or 9. The noise signals correspond to the first image pixel data. Referring to FIG. 14, the subtraction process can be accomplished by closing switches 182, 184 and 170 of the light reader circuit 16 (FIG. 14) to subtract the voltage across the second capacitor 154 from the voltage across the first capacitor 152.

Referring to FIG. 15, in block 306 light response output signals are sampled from the pixels 14 of the pixel array 12 and stored in the light reader circuit 16. The light response output signals correspond to the optical image that is being detected by the image sensor 10. Referring to FIGS. 13, 14 and 16 this can be accomplished by having the IN 120, SEL 122 and SAM2 lines 168 in a high state and RST 118 in a low state. The second capacitor 152 of the light reader circuit 16 stores a level shifted voltage of the photodiode 100 as the light response output signal.

Referring to FIG. 15, in block 308 a second reference output signal is then generated in the pixels 14 and stored in the light reader circuit 16. Referring to FIGS. 13, 14 and 16, this can be accomplished similar to generating and storing the first reference output signal. The RST line 118 is first driven high and then into a tri-state. The IN line 120 is then driven high to cause the transistor 112 to enter the triode region so that the voltage across the photodiode 100 is the voltage on IN line 120. The SEL 122 and SAM2 168 lines are then driven high to store the second reference output voltage in the first capacitor 154 of the light reader circuit 16. Process blocks 306 and 308 are repeated for each pixel 14 in the array 12.

Referring to FIG. 15, in block 310 the light response output signal is subtracted from the second reference output signal to create a normalized light response output signal. The normalized light response output signal is converted into a digital bit string to create normalized light output data that is stored in the second image buffers 32 and 34. The normalized light response output signals correspond to the second image pixel data. Referring to FIGS. 13, 14 and 16 the subtraction process can be accomplished by closing switches 170, 182 and 184 of the light reader 16 to subtract the voltage across the first capacitor 152 from the voltage across the second capacitor 154. The difference is then amplified by amplifier 180 and converted into a digital bit string by ADC 24 as light response data.

Referring to FIG. 15, in block 312 the noise data is retrieved from external memory. In block 314 the noise data is combined (subtracted) with the normalized light output data in accordance with one of the techniques shown in FIG. 3, 4, 5, 6, 7 or 8. The noise data corresponds to the first image and the normalized light output data corresponds to the second image. The second reference output signal is the same or approximately the same as the first reference output signal such that the present technique subtracts the noise data, due to reset noise, charge injection and clock feedthrough, from the normalized light response signal. This improves the signal to noise ratio of the final image data. The image sensor performs this noise cancellation with a pixel that has only three transistor. This image sensor thus provides noise cancellation while maintaining a relatively small pixel pitch. This process is accomplished using an external processor 72 and external memory 74.

The process described is performed in a sequence across the various rows of the pixels in the pixel array 12. As shown in FIG. 16, the n-th row in the pixel array may be generating noise signals while the n−l-th row generates normalized light response signals, where l is the exposure duration in multiples of a line period.

The various control signals RST, SEL, IN, SAM1, SAM2 and SUB can be generated in the circuit generally referred to as the row decoder 20. FIG. 18 shows an embodiment of logic to generate the IN, SEL, SAM1, SAM2 and RST signals in accordance with the timing diagram of FIG. 16. The logic may include a plurality of comparators 350 with one input connected to a counter 352 and another input connected to hardwired signals that contain a lower count value and an upper count value. The counter 352 sequentially generates a count. The comparators 350 compare the present count with the lower and upper count values. If the present count is between the lower and upper count values the comparators 350 output a logical 1.

The comparators 350 are connected to plurality of AND gates 356 and OR gates 358. The OR gates 358 are connected to latches 360. The latches 360 provide the corresponding IN, SEL, SAM1, SAM2 and RST signals. The AND gates 356 are also connected to a mode line 364. To operate in accordance with the timing diagram shown in FIG. 16, the mode line 364 is set at a logic 1.

The latches 360 switch between a logic 0 and a logic 1 in accordance with the logic established by the AND gates 356, OR gates 358, comparators 350 and the present count of the counter 352. For example, the hardwired signals for the comparator coupled to the IN latch may contain a count values of 6 and a count value of 24. If the count from the counter is greater or equal to 6 but less than 24 the comparator 350 will provide a logic 1 that will cause the IN latch 360 to output a logic 1. The lower and upper count values establish the sequence and duration of the pulses shown in FIG. 16. The mode line 364 can be switched to a logic 0 which causes the image sensor to function in a second mode.

The sensor 10 may have a plurality of reset RST(n) drivers 370, each driver 370 being connected to a row of pixels. FIGS. 19 and 20 show an exemplary driver circuit 370 and the operation of the circuit 370. Each driver 370 may have a pair of NOR gates 372 that are connected to the RST and SAM1 latches shown in FIG. 18. The NOR gates control the state of a tri-state buffer 374. The tri-state buffer 374 is connected to the reset transistors in a row of pixels. The input of the tri-state buffer is connected to an AND gate 376 that is connected to the RST latch and a row enable ROWEN(n) line.

FIGS. 21 and 22 show operation of the image sensor in a second mode also referred to as an extended dynamic range mode. In this mode the image provides a sufficient amount of optical energy so that the SNR is adequate even without the noise cancellation technique described in FIGS. 15 and 16. Although it is to be understood that the noise cancellation technique shown in FIGS. 15 and 16 can be utilized while the image sensor 10 is in the extended dynamic range mode. The extended dynamic mode has both a short exposure period and a long exposure period. Referring to FIG. 21, in block 400 each pixel 14 is reset to start a short exposure period. The mode of the image sensor can be set by the processor 72 to determine whether the sensor should be in the low noise mode, or the extended dynamic range mode.

In block 402 a short exposure output signal is generated in the selected pixel and stored in the second capacitor 154 of the light reader circuit 16.

In block 404 the selected pixel is then reset. The level shifted reset voltage of the photodiode 100 is stored in the first capacitor 152 of the light reader circuit 16 as a reset output signal. The short exposure output signal is subtracted from the reset output signal in the light reader circuit 16. The difference between the short exposure signal and the reset signal is converted into a binary bit string by ADC 24 and stored into the external memory 74 in accordance with one of the techniques shown in FIG. 2, 3, 8 or 9. The short exposure data corresponds to the first image pixel data. Then each pixel is again reset to start a long exposure period.

In block 406 the light reader circuit 16 stores a long exposure output signal from the pixel in the second capacitor 154. In block 408 the pixel is reset and the light reader circuit 16 stores the reset output signal in the first capacitor 152. The long exposure output signal is subtracted from the reset output signal, amplified and converted into a binary bit string by ADC 24 as long exposure data.

Referring to FIG. 21, in block 410 the short exposure data is retrieved from external memory. In block 412 the short exposure data is combined with the long exposure data in accordance with one of the techniques shown in FIG. 3, 4, 5, 6, 7 or 8. The data may be combined in a number of different manners. The external processor 72 may first analyze the image with the long exposure data. The photodiodes may be saturated if the image is too bright. This would normally result in a “washed out” image. The processor 72 can process the long exposure data to determine whether the image is washed out, if so, the processor 72 can then use the short exposure image data. The processor 72 can also use both the long and short exposure data to compensate for saturated portions of the detected image.

By way of example, the image may be initially set to all zeros. The processor 72 then analyzes the long exposure data. If the long exposure data does not exceed a threshold then N least significant bits (LSB) of the image is replaced with all N bits of the long exposure data. If the long exposure data does exceed the threshold then N most significant bits (MSB) of the image are replaced by all N bits of the short exposure data. This technique increases the dynamic range by M bits, where M is the exponential in an exposure duration ratio of long and short exposures that is defined by the equation l=2^(M). The replaced image may undergo a logarithmic mapping to a final picture of N bits in accordance with the mapping equation Y=2^(N) log₂(X)/(N+M).

FIG. 22 shows the timing of data generation and retrieval for the long and short exposure data. The reading of output signals from the pixel array 12 overlap with the retrieval of signals from memory 74. FIG. 22 shows timing of data generation and retrieval wherein a n-th row of pixels starts a short exposure, the (n−k)-th row ends the short exposure period and starts the long exposure period, and the (n−k−l)-th row of pixels ends the long exposure period. Where k is the short exposure duration in multiples of the line period, and l is the long exposure duration in multiples of the line period.

The memory controller 44 begins to retrieve short exposure data for the pixels in row (n−k−l) at the same time as the (n−k−l)-th pixel array is completing the long exposure period. At the beginning of a line period, the light reader circuit 16 retrieves the short exposure output signals from the (n−k)-th row of the pixel array 12 as shown by the enablement of signals SAM1, SAM, SEL(n−k) and RST(n−k). The light reader circuit 16 then retrieves the long exposure data of the (n−k−l)-th row.

The dual modes of the image sensor 10 can compensate for varying brightness in the image. When the image brightness is low the output signals from the pixels are relatively low. This would normally reduce the SNR of the resultant data provided by the sensor, assuming the average noise is relatively constant. The noise compensation scheme shown in FIGS. 15 and 16 improve the SNR of the output data so that the image sensor provides a quality picture even when the subject image is relatively dark. Conversely, when the subject image is too bright the extended dynamic range mode depicted in FIGS. 21 and 22 compensates for such brightness to provide a quality picture.

FIG. 23a shows an alternate embodiment of an image sensor that has a processor bus 70′ connected to the external processor 72 and a separate memory bus 70″ connected to the external memory 74. With such configuration the processor 72 may access data while the memory 74 is storing and transferring data. This embodiment also allows for slower clock speeds on the processor bus 70′ than the bus 68 of the embodiment shown in FIG. 1.

FIG. 23b shows another embodiment wherein the processor 72 is coupled to a separate data interface 500 and the external memory 74 is connected to a separate memory controller 44.

FIG. 24 shows another embodiment of an image sensor with a data interface 500 connected to the buffers 28, 30, 32 and 34. The interface 500 is connected to an external processor 72 by a processor bus 502. In this configuration the external memory 74 is connected to the processor 72 by a separate memory bus 504. For both still images and video capture the first and second images are provided to the external processor in an interleaving manner.

FIG. 25 discloses an alternate embodiment of an image sensor without the buffers 28, 30, 32 and 34. With this embodiment the ADC 24 is connected directly to the external processor 72. The processor 72 may perform computation steps such as combining (subtracting) the noise data with the normalized light output data, or the short exposure data with the long exposure data.

FIG. 26 discloses an external processor that contains a DMA controller 510, buffer memory 512 and a image processing unit 514. The image sensor 10 is connected to the DMA controller 510. The DMA controller 510 of the processor transfers the first and second image data to the memory 74 in an interleaved or concatenated manner. The DMA controller 510 can also transfer image data to the buffer memory 512 for processing by the image processing unit 514.

FIG. 27 shows another embodiment of an image sensor system 550. The system 550 includes an image sensor 552 that is coupled to a processor 554 by a first bus 556 and a second bus 558. The processor 554 may also be coupled to a memory device 560 by a memory bus 562 and a non-volatile memory device 564 by a non-volatile memory bus 566.

The image sensor 552 generates a first image(s) and a second image(s). By way of example, the first image may be the digitized normalized noise output signals when the system is in the low noise mode, or the short exposure data of the extended dynamic range mode. Likewise, the second image may be the digitized normalized light response output signals of the low noise mode, or the long exposure data of the extended dynamic range mode.

The image sensor 552 transfers the first and second images to the processor 554 in a time overlapping manner. The first image may be transferred across the first bus 556 while the second image is transferred across the second bus 558. It being understood that a time overlapping manner means that data of the second image is being transferred to the processor 554 while data of the first image is still be transmitted by the image sensor 552. By way of example, the image sensor 552 may transfer the images to the processor by interleaving the first and second images on a single bus, or transferring both images on dedicated busses 556 and 558. The image sensor 552 may transfer the image data from an internal data interface, memory controller, directly from an ADC, or any other on-board processor and/or memory interface.

The processor 554 may cause the first image to be stored in the memory device 560 and then later recombined with the second image. Alternatively, the memory device 560 may store the entire first and second images. The first and second images may then be retrieved and combined by the processor 554. As yet another alternative, the memory device 560 may store only a portion of the second image.

The non-volatile memory device 564 may be a read only memory (“ROM”) that contains embedded firmware. The firmware may include a program that causes the processor 554 to receive the first and second images in a time overlapping manner. By way of example, the program may cause the processor 554 to receive the images in an interleaved manner. Alternatively, the processor 554 may be configured to have a combination of firmware and hardware, or a pure hardware implementation for receiving the image data in a time overlapping manner.

As shown in FIG. 28, the processor 554 of the dual bus system 550 may contain an on-board DMA controller 566, a buffer memory 568 and processing unit 570 similar to the processor shown in FIG. 26. The DMA controller 566 may cause the image data to be stored and retrieved from the memory device 560.

FIG. 29 shows an embodiment of a dual port DMA controller 566 that has a plurality of buffers 572, 574, 576 and 578. Buffers 572 and 574, and 576 and 578 are coupled to the busses 556 and 558 by switches 580 and 582, respectively. The buffers 572 and 574, and 576 and 578 are coupled to the memory bus 562 by switches 584, 586 and 588. The buffers and switches may operate similar to the buffers 28, 30, 32 and 34, and switches 38, 40, 42, 48 and 54 of the image sensor shown in FIG. 1.

The DMA controller 566 may have a logic circuit 590 that causes the first image data to be stored in buffers 572 and 574 and the second image data to be stored in buffers 576 and 578. Buffers 574 and 578 may store data from the busses 556 and 558, respectively, while the memory device 560 stores first image data and second image data from buffers 572 and 576, respectively. Buffers 572 and 576 may then store data from busses 556 and 558 while buffers 574 and 578 provide data to memory 560. The buffers 572, 574, 576 and 578 may alternate between storing data from the busses 556 and 558 and providing data to the memory device 560. The DMA controller 566 can control the memory location of the image data within the memory device 560.

Although not shown, the image sensor systems shown in FIGS. 23a, 23b and 25 may also have a dual bus arrangement. The embodiments shown in FIGS. 23a and 23b may have dual busses for the processor 72 and/or memory 74.

It is the intention of the inventor that only claims which contain the term “means” shall be construed under 35 U.S.C. §112, sixth paragraph.

While certain exemplary embodiments have been described and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of and not restrictive on the broad invention, and that this invention not be limited to the specific constructions and arrangements shown and described, since various other modifications may occur to those ordinarily skilled in the art.

For example, although interleaving techniques involving entire lines of an image are shown and described, it is to be understood that the data may be interleaved in a manner that involves less than a full line, or more than one line. By way of example, one-half of the first line of image A may be transferred, followed by one-half of the first line of image B, followed by the second-half of the first line of image A, and so forth and so on. Likewise, the first two lines of image A may be transferred, followed by the first two lines of image B, followed by the third and, fourth lines of image A, and so forth and so on.

Additionally, the processor 72 and/or 554 may be a digital signal processor provided by Texas Instruments under the part designation TMS320DSC21, TMS320DSC25, TMS320DM270 or TMS320DM310, or a modified version of these parts. 

What is claimed is:
 1. An image capture apparatus, comprising: a pixel array that generates a first image and a second image in a time-overlapping manner, a pixel in the pixel array generating pixel signals for the first and second images separately; a bus across which the first image and the second image are transmitted in a time overlapping manner such that a transmission of the second image begins before a transmission of the first image is terminated; and a processor that is coupled to said pixel array across said bus, said processor receives the first and second images transmitted across said bus, the first image starts transmitting before the second image, the second image starts transmitting before the first image terminates its first-time ever transmission across said bus.
 2. The image capture apparatus of claim 1, wherein the first and second images are stored in two different buffer areas in said processor.
 3. The image capture apparatus of claim 1, wherein the first image is generated from pixel array line by line.
 4. The image capture apparatus of claim 1, wherein the first image is generated from the pixel array in one vertical scan. 